梨冠网蝽的线粒体基因组测序及臭虫次目科级水平的系统发育分析

doi:10.16380/j.kcxb.2023.07.008

摘要/Abstract

摘要： 【目的】为探究梨冠网蝽Stephanitis nashi线粒体基因组结构特征及臭虫次目(Cimicomorpha)科级水平的系统发育关系。【方法】利用高通量测序技术测定梨冠网蝽线粒体全基因组序列。选择已知的臭虫次目150个物种线粒体基因组作为内群，选择蝽次目(Pentatomomorpha)2个物种线粒体基因组作为外群，利用最大似然法(maximum likelihood, ML)和贝叶斯法(Bayesian inference, BI)重建臭虫次目科级水平的系统发育关系。【结果】梨冠网蝽的线粒体基因组(GenBank登录号: OP650254)全长为15 045 bp，包含37个基因［13个蛋白质编码基因(protein-coding genes, PCGs)、22个tRNA基因和2个rRNA基因］和一段非编码控制区。13个PCGs中除nad5的起始密码子为ATC外，其余PCGs的起始密码子都是ATT, ATA或ATG； cox2和nad4l具有不完整的终止密码子T，其余11个PCGs为完整的终止密码子TAA或TAG。所有tRNA基因均能形成典型的三叶草结构。rRNA基因rrnL全长1 237 bp，A+T含量为81.08%；rrnS全长为763 bp，A+T含量为82.04%。ML和BI构建的臭虫次目的系统发育关系是基本一致的；网蝽科(Tingidae)、臭虫科(Cimicidae)、榈蝽科(Thaumastocoridae)、盲蝽科(Miridae)、丝蝽科(Plokiophilidae)、驼蝽科(Microphysidae)、捷蝽科(Velocipedidae)、花蝽科(Anthocoridae)、姬蝽科(Nabidae)、粗股蝽科(Pachynomidae)和瘤蝽科(Phymatidae)均为单系群，而猎蝽科(Reduviidae)为非单系群，网蝽科与榈蝽科和猎蝽科部分种具有较近的亲缘关系。【结论】本研究利用线粒体基因组数据重建了臭虫次目的系统发育关系，支持猎蝽科为非单系群，其他11个科为单系群，有利于更加全面对臭虫次目系统发育和线粒体基因组学的理解。

关键词: 梨冠网蝽, 臭虫次目, 网蝽科, 线粒体基因组, 系统发育

Abstract: 【Aim】 To explore the structure characteristics of the mitochondrial genome of Stephanitis nashi and the phylogenetic relationships within Cimicomorpha at the family level. 【Methods】 The complete mitochondrial genome of S. nashi was sequenced by using high-throughput sequencing technology. The phylogenetic relationships within Cimicomorpha at the family level, with the mitochondrial genomes of 150 species known to Cimicomorpha as ingroups and those of two Pentatomomorpha species as outgroups, were reconstructed using maximum likelihood (ML) and Bayesian inference (BI) methods. 【Results】 The mitochondrial genome of S. nashi (GenBank accession no.: OP650254) is 15 045 bp in full-length, which contains 37 genes including 13 protein-coding genes (PCGs), 22 tRNA genes, two rRNA genes and a non-coding control region. Among the 13 PCGs, except that the start codon of nad5 is ATC, the start codons of the other PCGs are ATT, ATA or ATG. While cox2 and nad4l employ the incomplete T as the stop codon, the other 11 PCGs terminate with complete stop codons of TAA or TAG. All tRNA genes can be folded into typical cloverleaf structure. The lengths of the rRNA genes rrnL and rrnS are 1 237 and 763 bp, with the A+T content of 81.08% and 82.04%, respectively. Both ML and BI produced a similar phylogenetic relationships within Cimicomorpha: the families Tingidae, Cimicidae, Thaumastocoridae, Miridae, Plokiophilidae, Microphysidae, Velocipedidae, Anthocoridae, Nabidae, Pachynomidae and Phymatidae were monophyletic, respectively. However, the family Reduviidae was non-monophyletic. The Tingidae had close relationships to Thaumastocoridae and part of Reduviidae. 【Conclusion】 This study reconstructed the phylogenetic relationships within the Cimicomorpha based on the mitochondrial genome data, revealing the non-monophyly of the family Reduviidae and the monophyly of the other 11 families, and it will contribute to increasing our knowledge about the phylogeny and the mitogenomics of Cimicomorpha.

Key words: Stephanitis nashi, Cimicomorpha, Tingidae, mitochondrial genome, phylogeny

林兴雨, 赵特, 宋南. 梨冠网蝽的线粒体基因组测序及臭虫次目科级水平的系统发育分析[J]. 昆虫学报, 2023, 66(7): 934-945.

LIN Xing-Yu, ZHAO Te, SONG Nan. Sequencing of the mitochondrial genome of Stephanitis nashi (Hemiptera: Tingidae) and phylogenetic analysis of Cimicomorpha at the family level[J]. Acta Entomologica Sinica, 2023, 66(7): 934-945.

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梨冠网蝽的线粒体基因组测序及臭虫次目科级水平的系统发育分析

Sequencing of the mitochondrial genome of Stephanitis nashi (Hemiptera: Tingidae) and phylogenetic analysis of Cimicomorpha at the family level

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